Telephoto lens system

Abstract

A telephoto lens system having a relatively large aperture is composed of six lenses collected into four lens members, successively arranged, from the object side of the system to the image side, as follows: a first lens member including a positive lens whose convex surface faces the object side; a second lens member including a negative meniscus lens whose convex surface faces the object side and, a positive meniscus lens cemented to the negative meniscus lens; a third lens member including a positive lens whose convex surface faces the image side, and a biconcave lens cemented to the positive lens; and a fourth lens member consisting of a positive lens.

The aberrations of the telephoto lens system of the invention are reduced even though the aperture is relatively larger than the apertures of prior art lens.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to telephoto lens systems, and more particularly to a telephoto lens system having improved aberration correction.

2. Description of the Prior Art

Conventional telephoto lens have not been realized with a relative aperture exceeding 1 : 2.8, because telephoto lens that are this bright are difficult to correct for spherical aberration in the vicinity of g-line (453.8mμ) light.

SUMMARY OF THE INVENTION

The present invention provides a relatively bright telephoto lens system utilizing two cemented lenses in a Tele-Sonnar type of lens system, and arranged so that various aberrations are effectively corrected. The system includes four members successively arranged, from the object side of the system to the image side, as follows: a first lens member including a positive lens whose convex surface faces the object side; a second lens member having two lens with a composite positive refractive power and including a negative meniscus lens whose convex surface faces the object side, and a positive meniscus lens cemented to the negative meniscus lens; a third lens member having two lenses with a composite negative refractive power including a positive lens whose convex surface faces the image side, and a biconcave lens cemented to the positive lens; and a fourth lens member consisting of a positive lens.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention are illustrated in the accompanying drawing wherein:

FIG. 1 is a sectional view of a lens system according to the present invention;

FIGS. 2a, 2b and 2c illustrate, respectively, spherical aberration, astigmatism and distortion for the embodiment of Example I;

FIGS. 3a, 3b, and 3c illustrate, respectively, spherical aberration, astigmatism and distortion for the embodiment of Example II;

FIGS. 4a, 4b, and 4c illustrate, respectively, spherical aberration, astigmatism and distortion for the embodiment of Example III;

FIGS. 5a, 5b and 5c illustrate, respectively, spherical aberration, astigmatism and distortion for the embodiment of Example IV; and

FIGS. 6a, 6b, and 6c illustrate, respectively, spherical aberration, astigmatism and distortion for the embodiment of Example V.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 shows a Tele-Sonnar type lens system constructed in accordance with the present invention. The system includes four members successively arranged, from the object side of the system to the image side as follows: a first lens member including a positive lens L1 whose convex surface faces the subject side; a second lens member having positive refractive power including a negative meniscus lens L2 and a positive meniscus lens L3; a third lens member having negative refractive power including a positive lens L4 and a biconcave lens L5; and a fourth lens member consisting of a positive lens L6 whose convex surface faces the subject side. The convex surface of lens L2 faces the subject side of the system; and the convex surface of lens L3 is cemented to the concave side of lens L2. The convex surface of lens L4 faces the image side of the system and the biconcave lens L5 is cemented to the convex surface of lens L4.

The significance of the second and the third lens members in achieving the desired aberration correction may be explained with reference to the problems of a relatively bright conventional telephoto lens. It is possible to efficiently correct various aberrations with respect to light of a given wavelength. When the aperture is relatively large, excessive correction of spherical aberration is effected for relatively short wavelength in the vicinity of the g-line (435.8mμ), resulting in a large increase in coma. The resultant telephoto lens is not practical by reason of these deficiencies.

In the present invention, the third lens member consists of positive lens L4, whose convex surface faces the image side, whose radius of curvature r₇ < O, and is cemented to the biconcave lens L5. As a consequence, excessive correction of spherical aberration is decreased for light in the vicinity of the g-line. If the cemented surface were convex with respect to the subject side, then the efficiency as above mentioned would be reduced. Designating the refractive indexes and the Abbe numbers of the positive lens L4 and the negative lens L5 in the third lens member as μ4, μ5 and ν4, ν5, respectively, the condition of η4>η5, 5>( ν5 - ν4)> 0.5, ν4<35 and ν5 <35 will result in the efficient reduction of excessive correction.

In the case where the cemented surface is convex with respect to the subject side, resulting in excessive correction of spherical aberration for light in the vicinity of the g-line, the chromatic aberration of the entire lens system cannot be balanced. The second lens member of the present invention prevents an imbalance because the convex surfaces of lenses 2 and 3 face the subject side. This construction reduces chromatic aberration. If the condition of (ν3 - ν2)>14 is met, wherein ν 2 and ν 3 are the Abbe numbers of the negative L2 and positive lens L3 respectively, the chromatic aberration can be balanced more effectively.

Embodiments of the present invention are listed below:

EXAMPLE I

______________________________________
Thicknesses
Refractive Abbe
Radii        & Distance Indexes    numbers
______________________________________
r1
=     58.0
d1 = 7.778
η1 =1.713
νd1 =53.9
r2
=     305.630
d2 = 0.370
r3
=     38.148
d3 = 2.741
η2 =1.62374
νd2 =47.0
r4
=     24.689
d4 = 13.259
η3 =1.58913
νd3 =61.2
r5
=     216.711
d5 = 2.593
r6
=     ∞
d6 = 8.815
η4 =1.74077
νd4 =27.7
r7
=     -30.963
d7 = 1.259
η5 =1.72825
νd5 =28.3
r8
=     22.734
d8 = 24.074
r9
=     62.963
d9 = 9.630
η6 =1.68893
νd6 =31.1
r10
=     1247.453
______________________________________
Focal length f=100 mm, F number F=2.0
View angle 2W=18

Various aberrations in Example I are plotted in FIGS. 2a, 2b, and 2c where reference characters d, g, S and m represent, respectively, the d-line, g-line, sagittal rays and meridional rays.

EXAMPLE II

______________________________________
r1
=     61.667
d1 = 8.296
η1 =1.6935
νd1 =53.5
r2
=     306.773
d2 = 0.370
r3
=     37.370
d3 = 2.741
η2 =1.62004
νd2 =36.3
r4
=     22.370
d4 = 13.259
η3 =1.58913
νd3 =61.2
r5
=     189.613
d5 = 2.593
r6
=     -2222.222
d6 = 8.889
Θ4 =1.68893
νd4 =31.1
r7
=     -38.519
d7 = 1.185
η5 =1.64769
νd5 =33.9
r8
=     22.210
d8 = 23.330
r9
=     59.259
d9 = 8.890
η6 =1.64769
νd6 =33.9
r10
=     395.706
______________________________________
f=100 mm  F=2.0 2W=18

Various aberrations in Example II are plotted in FIGS. 3a, 3b and 3c.

EXAMPLE III

______________________________________
r1
=     62.222
d1 = 8.30
η1 =1.6935
νd1 =53.5
r2
=     306.773
d2 = 0.37
r3
=     35.704
d3 = 2.74
η2 =1.6398
νd2 =34.6
r4
=     21.630
d4 = 13.26
η3 =1.58913
νd3 =61.2
r5
=     159.919
d5 = 2.59
r6
=     2222.222
d6 = 8.89
η4 =1.69895
νd4 =30.0
r7
=     -44.444
d7 = 1.19
η5 =1.6398
νd5 =34.6
r8
=     21.591
d8 = 24.44
r9
=     53.333    d9 = 7.41
η6 =1.64769
νd6 =33.9
r10
=     185.383
______________________________________
f=100 mm F=2.0 2W=18

Various aberrations in Example III are plotted in FIGS. 4a, 4b and 4c.

EXAMPLE IV

______________________________________
r1
=     61.67
d1 = 8.30
η1 =1.6935
νd1 =53.5
r2
=     306.773
d2 = 0.37
r3
=     37.040
d3 = 2.74
η2 =1.62004
νd2 =36.3
r4
=     22.118
d4 = 13.26
η3 =1.58913
νd3 =61.2
r5
=     177.778
d5 = 2.59
r6
=     ∞
d6 = 8.89
η4 =1.68893
νd4 =31.1
r7
=     -40.459
d7 = 1.19
η5 =1.64769
νd5 =33.9
r8
=     21.994
d8 = 23.04
r9
=     59.259
d9 = 8.89
η6 =1.64769
νd6 =33.9
r10
=     356.104
______________________________________
f=100 mm, F=2.0, 2W=18

Various aberrations in Example IV are plotted in FIGS. 5a, 5b and 5c.

EXAMPLE V

______________________________________
r1
=     58.015
d1 = 8.22
η1 =1.717
νd1 =48.1
r2
=     311.111
d2 = 0.37
r3
=     38.148
d3 = 2.74
η2 =1.62606
νd2 =39.1
r4
=     22.593
d4 = 13.26
η3 =1.58913
νd3 =61.2
r5
=     200.000
d5 = 2.59
r6
=     ∞
d6 = 8.89
η4 =1.74
νd4 =28.2
r7
=     -34.815
d7 = 1.19
η5 =1.71736
νd5 =29.5
r8
=     22.797
d8 = 25.11
r9
=     63.661
d9 = 8.89
η6 =1.71736
νd6 = 29.5
r10
=     624.694
______________________________________
f=100 mm, F=2.0, 2W=18

Various aberrations in Example V are plotted in FIGS. 6a, 6b and 6c.

Although the optical systems of the present invention are much brighter than systems in the prior art, aberrations are corrected as well as in the conventional systems.

The telephoto ratio, or the ratio of the total length T.L. of the lens system from the foremost lens surface to the focal plane divided by the focal length f is listed for each of the five Examples of the telephoto lens system according to the present invention. These values are derived from the calculation of the aforementioned data. The less these values are, the less the size of the telephoto lens.

______________________________________
Telephoto ratio
Example
ΣD B.f.     T.L.    (T.L./f)
______________________________________
I      70.519   29.97    100.489 1.005
II     69.553   31.44    100.993 1.010
III    69.19    30.18    99.37   0.994
IV     69.27    31.19    100.46  1.005
V      71.26    29.22    100.48  1.005
______________________________________

where B.f. is back focal distance, ΣD = d₁ + d₂ + . . . . + d₉ and T.L. = ΣD + B.f.

It is believed that the advantages and improved results furnished by the telephoto lens system of the present invention will be apparent from the foregoing description of several preferred embodiments of the invention. Various changes and modifications may be made without departing from the spirit and scope of the invention as sought to be defined in the following claims.

Claims

1. A telephoto lens system having an aperture ratio of approximately 1:2 and a telephoto ratio of approximately 1.0, the system comprising four members successively arranged, from the object side of the system to the image side, as follows:

a. a first lens member including a positive meniscus lens whose convex surface faces the object side;

b. a second lens member having positive refractive power and including a negative meniscus lens whose convex surface faces the object side, and a positive meniscus lens cemented to the negative meniscus lens;

c. a third lens member having negative refractive power and including a positive lens whose more curved surface faces the image side, and a biconcave lens cemented to the positive lens; and

d. a fourth lens member including a positive lens.

2. A telephoto lens system according to claim 1, wherein the components of the lenses satisfy the relationships:

η4>η5,

5>(ν5 - ν4)> 0.5,

35 >ν4,

35 >ν5,

where η4, η5 and ν4, ν5 are the refractive indexes and Abbe numbers, respectively, of the positive and biconcave lens in the third lens member.

3. A telephoto lens system according to claim 1 wherein the components of the lens satisfy the relationship:

( ν3 - ν2) > 14,

where ν2, ν3 are the Abbe numbers of the negative and positive lenses respectively of the second lens member.

4. A telephoto lens system according to Claim 1 having the following data:

______________________________________

Thicknesses

Refractive Abbe

Radii & Distance Indexes numbers

______________________________________

r1

= 58.0

d1 = 7.778

η1 =1.713

νd=53.9

r2

= 305.630

d2 = 0.370

r3

= 38.148

d3 = 2.741

η2 =1.62374

νd2 =47.0

r4

= 24.689

d4 = 13.259

η3 =1.58913

νd3 =61.2

r5

= 261.711

d5 = 2.593

r6

= ∞

d6 = 8.815

η4 =1.74077

νd4 =27.7

r7

= -30.963

d7 = 1.259

η5 =1.72825

νd5 =28.3

r8

= 22.734

d8 = 24.074

r9

= 62.963

d9 = 9.630

η6 =1.68893

νd6 =31.1

r10

= 1247.453

______________________________________

Focal length f=100 mm, F number F=2.0

View Angle 2W=18°.

5. A telephoto lens system according to claim 1 having the following data:

______________________________________

Thicknesses

Refractive Abbe

Radii & Distance Indexes numbers

______________________________________

r1

= 61.667

d1 = 8.296

η1 =1.6935

νd1 =53.5

r2

= 306.773

d2 = 0.370

r3

= 37.370

d3 = 2.741

η2 =1.62004

νd2 =36.3

r4

= 22.370

d4 = 13.259

η3 =1.58913

νd3 =61.2

r5

= 189.613

d5 = 2.593

r6

= -2222.222

d6 = 8.889

η4 =1.68893

νd4 =31.1

r7

= -38.519

d7 = 1.185

η5 =1.64769

νd5 =33.9

r8

= 22.210

d8 = 23.330

r9

= 59.259

d9 = 8.890

η6 =1.64769

νd6 =33.9

r10

= 395.706

______________________________________

Focal length f=100 mm, F number F=2.0

View Angle 2W=18°.

6. A telephoto lens system according to claim 1 having the following data:

______________________________________

Thicknesses

Refractive Abbe

Radii & Distance Indexes numbers

______________________________________

r1

= 62.222

d1 = 8.30

η1 =1.6935

νd1 =53.5

r2

= 306.773

d2 = 0.37

r3

= 35.704

d3 = 2.74

η2 =1.6398

νd2 =34.6

r4

= 21.630

d4 = 13.26

η3 =1.58913

νd3 =61.2

r5

= 159.919

d5 = 2.59

r6

= 2222.222

d6 = 8.89

η4 =1.69895

νd4 =30.0

r7

= -44.444

d7 = 1.19

η5 =1.6398

νd5 =34.6

r8

= 21.591

d8 = 24.44

r9

= 53.333

d9 = 7.41

η6 =1.64769

νd6 =33.9

r10

= 185.383

______________________________________

Focal length f=100 mm, F number F=2.0

View Angle 2W=18°.

7. A telephoto lens system according to claim 1 having the following data:

______________________________________

Thicknesses

Refractive Abbe

Radii & Distance Indexes numbers

______________________________________

r1

= 61.67

d1 = 8.30

η1 =1.6935

νd1 =53.5

r2

= 306.773

d2 = 0.37

r3

= 37.040

d3 = 2.74

η2 =1.62004

νd2 =36.3

r4

= 22.118

d4 = 13.26

η3 =1.58913

νd3 =61.2

r5

= 177.778

d5 = 2.59

r6

= ∞

d6 = 8.89

η4 =1.68893

νd4 =31.1

r7

= -40.459

d7 = 1.19

η5 =1.64769

νd5 =33.9

r8

= 21.994

d8 = 23.04

r9

= 59.259

d9 = 8.89

η6 =1.64769

νd6 =33.9

r10

= 356.104

______________________________________

Focal length f=100 mm, F number F=2.0

View Angle 2W=18°.

8. A telephoto lens system according to claim 1 having the following data:

______________________________________

Thicknesses

Refractive Abbe

Radii & Distance Indexes numbers

______________________________________

r1

= 58.015

d1 = 8.22

η1 =1.717

νd1 =48.1

r2

= 311.111

d2 = 0.37

r3

= 38.148

d3 = 2.74

η2 =1.62606

νd2 =39.1

r4

= 22.593

d4 = 13.26

η3 =1.58913

νd3 =61.2

r5

= 200.000

d5 = 2.59

r6

= ∞

d6 = 8.89

η4 =1.74

νd4 =28.2

r7

= -34.815

d7 = 1.19

η5 =1.71736

νd5 =29.5

r8

= 22.797

d8 = 25.11

r9

= 63.661

d9 = 8.89

η6 =1.71736

νd6 =29.5

r10

= 624.694

______________________________________

Focal length f=100 mm, F number F=2.0

View Angle 2W=18°.